Explicit Solution of the Generalised Langevin Equation

Terlizzi, Ivan Di; Ritort, Fèlix; Baiesi, Marco

doi:10.1007/s10955-020-02639-4

“…of equation ( 55) -the present one involves a second term ∝ C q (t) due to thermal fluctuations. Note that the integration in the variable u in equation ( 54) runs from −∞, and this fact prevents a direct solution of the equation of motion by using the Laplace transform [50]. However, in order to determine the response of the average particle position to a sudden displacement X 0 imposed at time t = 0 from its stationary value X = 0, one can look for a solution X(t) of equation ( 55) with X(t) ≡ 0 for t < 0, and X(t) = X 0 at t = 0.…”

Section: Weak-coupling Approximationmentioning

confidence: 99%

Memory-induced oscillations of a driven particle in a dissipative correlated medium

Venturelli,

Gambassi

2023

New J. Phys.

3

0

View full text Add to dashboard Cite

The overdamped dynamics of a particle is in general affected by its interaction with the surrounding medium, especially out of equilibrium, and when the latter develops spatial and temporal correlations. Here we consider the case in which the medium is modeled by a scalar Gaussian field with relaxational dynamics, and the particle is dragged at constant velocity through the medium by a moving harmonic trap. This mimics the setting of an active microrheology experiment conducted in a near-critical medium. When the particle is displaced from its average position in the nonequilibrium steady state, its subsequent relaxation is shown to feature damped oscillations. This is similar to what has been recently predicted and observed in viscoelastic fluids, but differs from what happens in the absence of driving or for an overdamped Markovian dynamics, in which cases oscillations cannot occur. We characterize these oscillating modes in terms of the parameters of the underlying mesoscopic model for the particle and the medium, confirming our analytical predictions via numerical simulations.

show abstract

“…They involve the variance of the particle position at an arbitrary time t ≥ 0, x(t) 2 , with t = 0 the time defining the initial condition, computed over an ensemble of independent realizations of the colored noise ζ (t) defined by Equations ( 2). An analytical treatment of this problem requires the explicit solution of the generalized Langevin Equation ( 8), which is not trivial even in the simpler case of a constant trap stiffness and constant temperature [48]. Therefore, to address the problem of the performance of a Brownian Stirling heat engine described by Equations ( 2), ( 8), ( 13) and ( 14), we opt for numerical simulations of the corresponding stochastic dynamics.…”

Section: Modelmentioning

confidence: 99%

“…Although all these conditions are met by a colloidal heat engine operating in a complex fluid, to the best of our knowledge they have never been examined in the context of stochastic thermodynamic cycles. Therefore, it is of paramount importance to assess the role of viscoelasticity in the performance of this kind of engines, since the resulting frequency-dependent friction experienced by a colloidal particle can significantly impact the rate at which energy is dissipated into a viscoelastic bath [45][46][47][48].…”

Section: Introductionmentioning

confidence: 99%

Work Extraction and Performance of Colloidal Heat Engines in Viscoelastic Baths

Gomez-Solano

¹

2021

View full text Add to dashboard Cite

A colloidal particle embedded in a fluid can be used as a microscopic heat engine by means of a sequence of cyclic transformations imposed by an optical trap. We investigate a model for the operation of such kind of Brownian engines when the surrounding medium is viscoelastic, which endows the particle dynamics with memory friction. We analyze the effect of the relaxation time of the fluid on the performance of the colloidal engine under finite-time Stirling cycles. We find that, due to the frequency-dependence of the friction in viscoelastic fluids, the mean power delivered by the engine and its efficiency can be highly enhanced as compared to those in a viscous environment with the same zero-shear viscosity. In addition, with increasing fluid relaxation time the interval of cycle times at which positive power output can be delivered by the engine broadens. Our results reveal the importance of the transient behavior of the friction experienced by a Brownian heat engine in a complex fluid, which cannot be neglected when driven by thermodynamic cycles of finite duration.

show abstract

“…They involve the variance of the particle position at an arbitrary time t, x(t) 2 , computed over an ensemble of independent realizations of the colored nosie ζ(t) defined by Equations ( 2). An analytical treatment of this problem requires the explicit solution of the generalized Langevin equation ( 8), which is not trivial even in the simpler case of a constant trap stiffness [45]. Therefore, to address the problem of the performance of a Brownian Stirling heat engine described by Equations ( 2), ( 8), ( 11) and ( 12), we opt for numerical simulations of the corresponding stochastic dynamics.…”

Section: Modelmentioning

confidence: 99%

“…Although all these conditions are met by a colloidal heat engine operating in a complex fluid, to the best of our knowledge they have never been examined in in the context of stochastic thermodynamic cycles. Therefore, it is of paramount importance to assess the role of viscoelasticity in the performance of this kind of engines, since the resulting frequency-dependent friction experienced by a colloidal particle can significantly impact the rate at which energy is dissipated into a viscoelastic bath [42,43,44,45].…”

Section: Introductionmentioning

confidence: 99%

Work extraction and performance of colloidal heat engines in viscoelastic baths

Gomez-Solano

2020

Preprint

0

View full text Add to dashboard Cite

A colloidal particle embedded in a fluid can be used as a microscopic heat engine by means of a sequence of cyclic transformations imposed by an optical trap. We investigate a model for the operation of such kind of Brownian engines when the surrounding medium is viscoelastic, which endows the particle dynamics with memory friction. We analyze the effect of the relaxation time of the fluid on the performance of the colloidal engine under finite-time Stirling cycles. We find that, due to the frequency-dependence of the friction in viscoelastic fluids, the mean power delivered by the engine and its efficiency can be highly enhanced as compared to those in a viscous environment with the same zero-shear viscosity. In addition, with increasing fluid relaxation time the interval of cycle times at which positive power output can be delivered by the engine broadens. Our results reveal the importance of the transient behavior of the friction experienced by a Brownian heat engine in a complex fluid, which cannot be neglected when driven by thermodynamic cycles of finite duration.

show abstract

Explicit Solution of the Generalised Langevin Equation

Cited by 13 publications

References 38 publications

Memory-induced oscillations of a driven particle in a dissipative correlated medium

Memory-induced oscillations of a driven particle in a dissipative correlated medium

Work Extraction and Performance of Colloidal Heat Engines in Viscoelastic Baths

Work extraction and performance of colloidal heat engines in viscoelastic baths

Contact Info

Product

Resources

About